The physico-chemistry of the Earth's atmosphere has been one of the main subjects of studies over last years. In particular, the composition of the atmosphere is indeed very important to understand chemical processes linked to depletion of stratospheric ozone and greenhouse effect. The vertical concentration profiles of atmospheric gases can be provided by remote sensing measurements, but they require the accurate knowledge of the parameters involved: line positions, transition intensities, pressure-broadened half-widths, pressure-induced frequency shifts and their temperature dependence. In particular, the collisional broadening parameters have a crucial influence on the accuracy of spectra calculations and on reduction of remote sensing data. As far as astrophysics is concerned, it is well-known that the knowledge of very accurate rest frequencies is important for astrophysical purposes: precise frequencies of rotational transitions are essential in studies of molecular excitation, radiative transfer, systematic velocity gradients and ambipolar diffusion in star-forming regions, and also simply for the identification of new species. Rotational spectroscopy, thanks to its intrinsic high resolution, is a powerful tool for providing most of the information mentioned above: accurate or even very accurate rotational transition frequencies, accurate spectroscopic as well as hyperfine parameters, accurate pressure-broadening coefficients and their temperature dependence. For instance, by exploiting the Lamb-dip technique it is possible to further increase the high resolution power of rotational spectroscopy and then resolve hyperfine structures and/or measure very accurate rest frequencies. With respect to collisional phenomena and line shape analysis studies, by applying the source frequency modulation technique it has been found that rotational spectroscopy may provide very good results: not only this technique does not produce uncontrollable instrumental distortions or broadenings, but also, having an high sensitivity, it is particularly suitable for this kind of investigations.

C. Puzzarini, G. Cazzoli (2006). Rotational Spectroscopy: A Powerful Tool for Atmospheric and Interstellar-Space Chemistry. PRAGA : ITC Press.

Rotational Spectroscopy: A Powerful Tool for Atmospheric and Interstellar-Space Chemistry

PUZZARINI, CRISTINA;CAZZOLI, GABRIELE
2006

Abstract

The physico-chemistry of the Earth's atmosphere has been one of the main subjects of studies over last years. In particular, the composition of the atmosphere is indeed very important to understand chemical processes linked to depletion of stratospheric ozone and greenhouse effect. The vertical concentration profiles of atmospheric gases can be provided by remote sensing measurements, but they require the accurate knowledge of the parameters involved: line positions, transition intensities, pressure-broadened half-widths, pressure-induced frequency shifts and their temperature dependence. In particular, the collisional broadening parameters have a crucial influence on the accuracy of spectra calculations and on reduction of remote sensing data. As far as astrophysics is concerned, it is well-known that the knowledge of very accurate rest frequencies is important for astrophysical purposes: precise frequencies of rotational transitions are essential in studies of molecular excitation, radiative transfer, systematic velocity gradients and ambipolar diffusion in star-forming regions, and also simply for the identification of new species. Rotational spectroscopy, thanks to its intrinsic high resolution, is a powerful tool for providing most of the information mentioned above: accurate or even very accurate rotational transition frequencies, accurate spectroscopic as well as hyperfine parameters, accurate pressure-broadening coefficients and their temperature dependence. For instance, by exploiting the Lamb-dip technique it is possible to further increase the high resolution power of rotational spectroscopy and then resolve hyperfine structures and/or measure very accurate rest frequencies. With respect to collisional phenomena and line shape analysis studies, by applying the source frequency modulation technique it has been found that rotational spectroscopy may provide very good results: not only this technique does not produce uncontrollable instrumental distortions or broadenings, but also, having an high sensitivity, it is particularly suitable for this kind of investigations.
2006
The 19th International Conference on High Reolution Molecular Spectroscopy
43
43
C. Puzzarini, G. Cazzoli (2006). Rotational Spectroscopy: A Powerful Tool for Atmospheric and Interstellar-Space Chemistry. PRAGA : ITC Press.
C. Puzzarini; G. Cazzoli
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/38822
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